Integrating two‐dimensional water temperature simulations into a fish habitat model to improve hydro‐ and thermopeaking impact assessment

Storage hydropower plants, which are an important component of energy production in Switzerland, can lead to hydro‐ and thermopeaking, affecting river habitats and organisms. In this study, we developed an approach for integrating water temperature simulations into a habitat model to assess the impa...

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Bibliographic Details
Published in:River research and applications 2023-03, Vol.39 (3), p.501-521
Main Authors: Antonetti, Manuel, Hoppler, Luca, Tonolla, Diego, Vanzo, Davide, Schmid, Martin, Doering, Michael
Format: Article
Language:English
Subjects:
Aquatic habitats
Availability
brown trout
Dewatering
Environmental restoration
Fish
Floodplains
Flow velocity
Habitat selection
habitat suitability curves
Habitats
Heterogeneity
High flow
Hydroelectric plants
Hydroelectric power
Hydroelectric power plants
Hydrology
hydropeaking
Impact assessment
Juveniles
Rivers
Salmo trutta
Simulation
Spatial distribution
Storage
Stranding
Switzerland
Temperature preferences
Thermal stress
Thermodynamic models
thermodynamic simulation
thermopeaking
thermoregulation
Trout
Water depth
Water temperature
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Summary:Storage hydropower plants, which are an important component of energy production in Switzerland, can lead to hydro‐ and thermopeaking, affecting river habitats and organisms. In this study, we developed an approach for integrating water temperature simulations into a habitat model to assess the impact of both hydro‐ and thermopeaking on the availability of suitable fish habitats. We focused on the habitat requirements of juvenile brown trout (Salmo trutta) in a semi‐natural braided floodplain along the Moesa River (Southern Switzerland) in early summer. First, we defined different scenarios (with and without hydropeaking) based on the local hydrological and meteorological conditions. Second, we used a two‐dimensional depth‐averaged hydro‐ and thermodynamic model to simulate the spatial distributions of water depth, flow velocity, and water temperature. Third, we applied generalized preference curves for juvenile brown trout to identify hydraulically suitable habitats, and developed a new index to assess the availability of thermally suitable habitats. Finally, we quantified the extent to which hydraulically and thermally suitable habitats overlap in space and time. During both base and peak flow phases, most of the hydraulically and thermally suitable habitats are located in the side channels. High flow conditions combined with strong cold‐thermopeaking lead to a higher thermal heterogeneity. However, disconnected habitats originate in the dewatering zone, increasing the risk of stranding as well as thermal stress. By helping to better understand the effects of thermopeaking on the availability of fish habitats, our approach could contribute to the design and evaluation of ecological restoration in hydropeaking rivers.
ISSN:1535-1459
1535-1467
DOI:10.1002/rra.4043